認識微生物

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Transcript 認識微生物

Transcription(I)
王之仰

Transcription is a complex process
involving many layers of regulation.

Repressor and activator proteins
recognize and bind to specific
regions of DNA to control the
transcription of a nearby gene.

In E. coli, about half of genes are
clustered into operons, each of
which encodes enzymes
involved in a particular
metabolic pathway or proteins
that interact to form one
multisubunit protein.

All the genes within an operon
are coordinately regulated.

Transcription of operons is
controlled by an interplay
between RNA polymerase and
specific repressor and activator
proteins.

E. coli RNA polymerase must
be associated with one of a
small number of σ(sigma)
factors.

The most common one in
eubacterial cells is σ70.

σ70 binds to RNA polymerase and
to promoter DNA sequences,
bringing the RNA polymerase to a
promoter.

σ70 recognizes and binds to both
a six-base pair sequence
centered at -10 and a sevenbase pair sequence centered at
-35 from the +1 transcription
start.

E. coli RNA polymerase binds to the
promoter region DNA from -50 to 20 through interactions with DNA.

E. coli RNA polymerase binds to the
promoter region DNA from -50 to 20 through interactions with DNA
that do not depend on the
sequence.

σ70 can assist the RNA polymerase
in separating the DNA strands at
the transcription start site and
inserting the coding
strand into the active site of the
polymerase so that transcription
starts at +1.

The optimal σ70-RNA polymerase
promoter sequence, determined as the
consensus sequence of multiple strong
promoters, is TTGACAT (-35)-15-17 bpTATAAT (-10).

σ70 acts as an initiation factor required
for transcription initiation but not for
RNA-strand elongation once initiation
has taken place.

When E. coli is in an environment that
lacks lactose, synthesis of lac mRNA is
repressed so that cellular energy is not
wasted synthesizing enzymes the cell
cannot use.

E. coli preferentially metabolize glucose
and lactose is metabolized at a high rate
only when lactose is present and glucose
is largely depleted from the medium.

Transcription of the lac operon under
different conditions is controlled by lac
repressor and catabolite activator
protein (CAP). Each of which binds to a
specific DNA sequence in the lac
transcription-control region.

For transcription of the lac operon to
begin, the σ70 subunit must bind to the
lac promoter at the -35 and -10
promoter sequences; when no lactose is
present, the lac repressor binds to a
sequence called the lac operator, which
overlaps the transcription start site.

When lactose is present, it binds to
specific binding sites in each subunit of
the tetrameric lac repressor, causing a
conformational changes in the protein
that makes it dissociate from the lac
operator.

Once glucose is depleted from the media
and the intracellular glucose
concentration falls, E. coli respond by
synthesizing cyclic AMP.

As the concentration of cAMP increases,
it binds to a site in each subunit of the
dimeric CAP protein allowing the protein
to bind to the CAP site in the lac
transcription-control region.

The bound CAP-cAMP complex interacts
with the polymerase bound to the
promoter, stimulating the rate of
transcription initiation.

The tetrameric lac repressor actually
binds to two sites simultaneously, one at
the primary operator (lacO1) that
overlaps the region of DNA bound by
RNA polymerase at the promoter and at
one of two secondary operators
centered at +412 (lacO2) and 82(lacO3).

Simultaneous binding of the tetrameric
lac repressor to the primary lac operator
O1 and one of the two secondary
operators is possible because DNA is
quite flexible.

These secondary operators function to
increase the local cencentration of lac
repressor in the micro-vicinity of the
primary operator where repressor
repressor binding blocks RNA
polymerase binding.

Since the equilibrium of binding
reactions depends on the concentration
of the binding partners, the resulting
increased local concentration of lac
repressor in the vicinity of O1 increases
repressor binding to O1.

Mutation of only O2 or O3 reduces
repression twofold, indicating that
either one of these secondary operators
provides most of the stimulation of
repression.

Promoters that support a high rate of
transcription initiation have -10 and -35
sequences similar to the ideal promoter
shown previously and are called strong
promoter.

Those that support a low rate of
transcription initiation differ from this
ideal sequence and are called weak
promoters.

Transcription of most E. coli is involved
in a specific repressor that binds to the
operator region of a gene or operon,
thereby blocking transcription initiation.

Specific activator proteins, such as CAP
in the lac operon, control transcription
of a subset of bacterial genes that have
binding sites for the activator.

Specific activator proteins, such as CAP,
and others bind to DNA together with
RNA polymerase, stimulating
transcription from a specific promoter.

An activator can be modulated by cAMP
or by phosphorylation.

Most E. coli promoters interact with σ70
RNA polymerase.

Alternative σ-factors are required for the
transcription of sets of genes with
related functions involved in the
response to heat shock or nutrient
deprivation, motility, or sporulation in
G(-) bacteria.

Streptomyces encodes 63 σ-factors ;
most are structurally and functionally
related to σ70; but one class is
unrelated, represented in E. coli by σ54.

Transcription of genes by RNA
polymerases containing σ54 is regulated
solely by activators whose binding sites
in DNA, referred to as enhancers,
located 80-160 bps upstream
from the start site.

The best-characterized σ54-activator-
the NtrC protein-stimulates transcription
of the glnA gene; glnA encodes the
enzyme glutamine synthetase, which
synthesizes the amino acid glutamine
from glutamic acid and ammonia.

The σ54-RNA polymerase binds to the
glnA promoter but does not melt the
DNA strands and initiate transcription
until it is activated by NtrC, a dimeric
protein; NtrC is regulated by a protein
kinase called NtrB.

In response to low levels of glutamine,
NtrB phosphorylates NtrC, which then
binds to an enhancer upstream of the
glnA promoter.

Enhancer-bound phosphorylated NtrC
then stimulates the σ54-polymerase
bound at the promoter to separate the
DNA strands and initiate transcription.

Electron microscopy studies have shown
that phosphorylated NtrC bound at
enhancers and σ54-polymerase bound at
the promoter directly interact, forming a
loop in the DNA between the binding
sites.

NtrC has ATPase activity, and ATP
hydrolysis is required for activation of
bound σ54-polymerase by
phosphorylated NtrC; ATP hydrolysis
supplies the energy required for melting
the DNA strands. In contrast, the σ70polymerase does not require ATP
hydrolysis to separate the strands at a
start site.

Control of the E. coli glnA gene depends
on two proteins, NtrC and NtrB- twocomponent regulatory systems control
many responses of bacteria to changes
in their environment.

The E. coli proteins, PhoR and PhoB,
regulate transcription in response to the
concentration of free phosphate. PhoR
is a transmembrane protein, located in
the inner membrane, whose periplasmic
domain binds phosphate with moderate
affinity and whose cytosolic domain has
protein kinase activity; PhoB is a
cytosolic protein.

Large protein pores in the E.coli outer
membrane allow ions to diffuse freely
between the external environment and
the periplasmic space. When the
phosphate concentration in the
environment falls, it also falls in the
periplasmic space, causing phosphate to
dissociate from the PhoR periplasmic
domain. This causes a conformational
change in the PhoR cytoplasmic domain
that activates its protein kinase activity.

The activated PhoR initially transfers a
γ-phosphate from ATP to a histidine (H)
side chain in the PhoR kinase domain.

The same phosphate is then transferred
to a specific aspartic acid (D) side chain
in PhoB, converting PhoB from an
inactive to an active transcriptional
activator. Phosphorylated, active PhoB
then induces transcription from several
genes that help the cell cope with low
phosphate conditions.

Other bacterial responses are regulated
by two proteins; one protein, called a
sensor, contains a transmitter domain
homologous to the PhoR protein kinase
domain.

The transmitter domain of the sensor
protein is regulated by a second unique
protein domain that senses
environmental changes.

The second protein, called a response
regulator, contains a receiver domain
homologous to the region of PhoB that is
phosphorylated by activated PhoR.

The receiver domain of the response
regulator is associated with a second
domain that determines the protein’s
function.

The activity of this second functional
domain is regulated by phosphorylation
of the receiver domain; The transmitter
domain of a specific sensor protein will
phosphorylate only the receiver domains
of specific response regulators.

NtrB and NtrC function as sensor and
response regulator proteins in the two-
component regulatory system that
controls transcription of glnA.